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浙江大学学报(工学版)
浙江大学学报(工学版)  2026, Vol. 60 Issue (3): 651-660    DOI: 10.3785/j.issn.1008-973X.2026.03.021
动力工程     
级间燃烧室与低压涡轮导叶耦合热斑迁移特性
牛子翔1(),吴涵1,卢启昊1,赵兰芳1,2,朱志新1,*(),王高峰1
1. 浙江大学 航空航天学院,浙江 杭州 310027
2. 中国航发湖南动力机械研究所,湖南 株洲 412002
Hot-spot migration characteristic in coupled interstage combustor–low-pressure turbine vane system
Zixiang NIU1(),Han WU1,Qihao LU1,Lanfang ZHAO1,2,Zhixin ZHU1,*(),Gaofeng WANG1
1. School of Aeronautics and Astronautics, Zhejiang University, Hangzhou 310027, China
2. AECC Hunan Aviation Powerplant Research Institute, Zhuzhou 412002, China
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摘要:

为了研究涡轮级间燃烧温升和高温燃气对导叶内流动的影响,基于级间燃烧室与涡轮流道紧凑耦合的试验平台,在不同来流空气温度和燃料质量流量的工况下对导叶出口截面的温度场分布进行数值仿真和试验测量. 研究发现,级间燃烧的热斑形状不会随着级间温升、高温燃气温度、组分的改变发生明显变化. 对比试验与仿真结果,解释了级间燃烧室出口热斑形状与流场的关系. 结果显示,级间温升与高温燃气参数不会对导叶流场及热斑迁移特性产生显著的影响. 级间燃烧流场的结构主要取决于火焰稳定装置对涡轮部件的干涉,热斑迁移主要取决于流场结构.
关键词: 级间涡轮燃烧室(ITB)预混燃烧燃烧室性能出口温度分布热斑迁移耦合传热    
Abstract:

Numerical simulation and experimental measurement of the temperature field at the vane exit plane were conducted on a compactly coupled experimental platform integrating an interstage combustor and a turbine flow passage in order to analyze the effect of interstage combustion–induced temperature rise and high-temperature gas on the internal flow of turbine vane. Tests were performed under various operating conditions with different inlet air temperature and fuel mass flow rate. Results show that the hot-spot shape generated by interstage combustion exhibits no significant variation with change in interstage temperature rise, high-temperature gas temperature and gas composition. The relationship between the hot-spot pattern at the interstage combustor outlet and the corresponding flow field was clarified by comparing experimental and numerical results. Results demonstrate that variation in interstage temperature rise and high-temperature gas parameter has negligible effect on the vane flow field and hot-spot migration characteristic. The flow structure of the interstage combustion system is primarily governed by the interference of the flame stabilization device with the turbine component, while hot-spot migration is mainly determined by the flow-field structure.
Key words: interstage turbine burner (ITB)    premixed combustion    combustor performance    exit temperature distribution    hot-spot migration    coupled heat transfer
收稿日期: 2025-07-01 出版日期: 2026-02-04
:  V 231  
基金资助: 国家重大科技专项资助项目(J2019-III-0006-0049);国家重点研发计划资助项目(2021YFA0716202);国家自然科学基金资助项目 (U2341282).
通讯作者: 朱志新     E-mail: 22224045@zju.edu.cn;zhu_z_x@zju.edu.cn
作者简介: 牛子翔(1996—),男,硕士生,从事燃烧室与涡轮耦合的研究. orcid.org/0009-0007-9782-4661. E-mail:22224045@zju.edu.cn
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引用本文:

牛子翔,吴涵,卢启昊,赵兰芳,朱志新,王高峰. 级间燃烧室与低压涡轮导叶耦合热斑迁移特性[J]. 浙江大学学报(工学版), 2026, 60(3): 651-660.

Zixiang NIU,Han WU,Qihao LU,Lanfang ZHAO,Zhixin ZHU,Gaofeng WANG. Hot-spot migration characteristic in coupled interstage combustor–low-pressure turbine vane system. Journal of ZheJiang University (Engineering Science), 2026, 60(3): 651-660.

链接本文:

https://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2026.03.021        https://www.zjujournals.com/eng/CN/Y2026/V60/I3/651

图 1  级间燃烧试验模型的结构与测量截面位置示意图
图 2  蒸发槽火焰稳定器的结构图
图 3  蒸发槽火焰稳定器的原理图
测量区域测量截面测量参数测点数
进口4.5截面总压$ {p}_{\text{t}45} $2支5点
进口4.5 '截面外壁静压$ {p}_{\rm s45S} $3点
进口4.5 '截面内壁静压$ {p}_{\rm s45H} $3点
进口4.5 '截面温度$ {T}_{\text{t}45} $2支2点
出口5.5截面温度$ {T}_{\text{t55}} $10支8点
出口5.5截面内壁静压$ {p}_{\rm s55H} $3点
出口5.5截面总压$ {p}_{\text{t55}} $2支5点
表 1  测量参数及测点布局
图 4  截面5.5的温度测量区域
图 5  级间燃烧–涡轮耦合试验测试系统的示意图
图 6  计算流体域与网格划分
图 7  不同网格量模型仿真得到的截面平均总温沿轴向的分布
工况?a/(kg·s?1)Tt45/K?p/(g·s?1)
Case1a0.36000.27
Case1b0.36000.33
Case1c0.36000.40
Case2a0.36500.27
Case2b0.36500.40
表 2  级间燃烧的试验工况
图 8  总压恢复系数随进口马赫数的变化
图 9  Case1出口截面温度云图
图 10  Case2出口截面温度云图
图 11  不同工况下出口平均温度沿径向的分布
图 12  低压涡轮导叶出口温度的仿真结果与试验结果对比
图 13  Case1工况温度场沿轴向分布图
图 14  Case1b的导叶表面温度分布和流线
图 15  Case1b工况的热斑区域和流场对比
图 16  Case1b工况的出口温度、流线和涡量分布
图 17  导叶下游Q准则沿轴向截面分布与等值面分布
图 18  导叶下游轴向截面温度分布及 Q 准则等值面
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